DE10019305C2 - Handguns tool - Google Patents

Abstract

The hollow landing technique is used for civilian purposes by means of the handheld fire tool, for the sudden removal of material of any shape and cross-section. The material is displaced or structurally destroyed by the extraordinarily high impact pressure of a gas jet generated by means of hollow charge detonation and then compressed, tunneled and swirled in itself. DOLLAR A The pressure of the detonating shaped charge is first concentrated in a focal point in the handheld fire tool, whereby an extremely high pressure can arise. This focal point is accelerated via secondary charges and compressed or expanded or otherwise influenced by means of upstream elements. DOLLAR A With the handheld fire tool it is very effective to demolish old industrial plants or other buildings in densely populated areas. It is also possible to sight a drilling site to be inserted and then suddenly to produce the hole of any shape after the shaped charge has been ignited. This application is also likely to be an advantageous application for mechanical engineering or similar industries.

Description

The invention relates to a handheld fire tool for dispensing a compactor tied, tunneled and swirled gas jets for the introduction of Holes and various holes, geobores etc.

Hollow charge techniques are usually made from military weapons systems known. As armor-piercing weapons are a variety of Ge fired shells, grenades and missiles, the essential Be part is a shaped charge.

From US 48 62 804 is a hemispherical charge with behind it Parabolic hollow charge known, the hemisphere hollow charge a first pan break through.

A disadvantage of the proposed structure is that the outer contour of the Hollow charge does not correspond to the inner shape, therefore only one partial use of the available energy potential is possible is. In terms of flow technology, it is not only the parabolic hollow charge caused by the Hemispherical hollow charge, but by the edge formation of the Hollow body and the deformation of the parabolic hollow body by negative pressure also the function of the parabolic hollow charge.

Another disadvantage of the hollow charge proposed with US 48 62 804 is that the wall thickness of the explosive device is constant, that stands in the way of optimal function. Timing problems Another disadvantage is the proposed delayed detonators the proposed solution. During the first implosion process, which is caused by the Such a hollow spherical charge causes such an explosion le, the parabolic body, including the explosives, will destroy from the outset. First there is a tearing of the front part of the main body can be expected, the formation of a tip is prevented with subsequent gas pressure build-up. The focus is with that unable to settle and stretch.

The one caused by the structure of the proposed solution is extraordinary difficult initiation of the required even ignition process, with the consequence of the uneven burning of the shaped charge, that of its width difficult alignment, the chosen parallel parabolic load form, let in the destruction of the main body after detonation of the hemisphere expect charge.  

With US 37 26 224 a projectile designed as a hollow body was proposed beaten, the ver by a hollow charge arranged in rotation should be set. In addition to the rotation of the projectile, the Hollow charge beam can be rotated axially.

However, the proposed solution contains serious contradictions in fluidic terms. The rotational movement of the hollow body over is also not adequately carried on the shaped charge, because the outer skin parameter ter, especially the shape of the outer skin, not transferable to the rotation are. Furthermore, it is noteworthy that the proposed hollow inner body generally from the developed detonation wave, the collapse, not him and is therefore likely to be destroyed.

US 31 46 711 contains a conical primitive hollow charge, whereby a wing-like projectile offset axial rotation and at the same time to be accelerated by a shaped charge.

The proposed solution, however, has several fundamental contradictions sayings that result from disregarding the ratio of inertia to accelerating mass results. The highest burnup described The velocity of the shaped charge contradicts the inertia behavior of the wing floor. Depending on the burning rate, the Expected propeller. The projectile will accelerate, however penetrate through the resulting focal point. During the Ent The collapse are the speeds of the resulting Plasma and the focus so high that the inertia of the projectile it stands in the way of its function itself. Side swirls and braking Solutions in the side wings are further disadvantages of the proposed solution solution.

DE 36 22 680 A1 describes a cylindrical shaped charge with tulip-shaped ger deposit. It is said to be a two-stage shaped charge by means of a grenade fired to penetrate inactive and active armor. The application of simple, variable cone shaped charges derived from Cone sections in which a pre-gas and a main gas jet pass through hitting the active armor serves the disadvantage that on everyone Case when the main body is detonated.

The known DE-PS 977 835 shows a shaped charge for generating cut like effects. There are cylinders and cones, some of them off-center sedentary primitive hollow bodies and shaped charges described, with in itself effect, depending on the rate of combustion of the detonation substance fe.  

The fact that the collapse and the focus generation mostly by the In shape of the hollow body is guaranteed, the use of the Detona potential and thus the explosive masses are not very effective. A part the external forms described also have a negative influence solution from the outside, because here no swirling process takes place there is only symmetrical continuity. The proposed cone and Hollow cylinder charges cannot optimally use the explosives po Ensure potentials as there are negative eddy currents within the explosive counteract the collapse as it arises.

Unintended swirling in the rear of the shaped charges on the inner channel ten also have a braking effect on the development of the focus or collapse in terms of speed, shape and force of the focal point tes.

The lack of coordination of the inner and outer shape of the shaped charges decisive for the development of the optimal focus and the production the plasma jet with its plasma tip leaves the application the solution described only for cutting relatively thin materials.

Finally, DE-AS 11 42 537 became a rotationally symmetrical hollow explosive charge described. The mostly described training courses the shaped charge body have a cylindrical shape, the inside already di have verse curves, radii and surfaces, but due to the used Insulation made of gypsum, cement, etc., has a significant impact on its actual effect be reduced. The mostly shaped cylindrical charges on the outside create side vortices. A rear detonation wave can also cannot be intercepted by the deposits described. With the with the The first figure shown shaped charge is a partially backward movement Detonation wave through the concave curved interior and exterior contours. The central insert means that the Detonation wave no collapse and therefore no focus can. Instead, it is separated into segments of a circle suppressed. A rotating gas jet is not with the arrangement described produced.

Common disadvantage of the above solutions is that it is are bodies or hollow forms that are destroyed in the detonation. As a result, the full utilization of the energy potential of the De used toning agent not available.

The invention seeks to remedy this. The invention as in the claims Chen is marked, the task solves a handheld fire tool abrupt removal of material of any cut-out shape and cross section. The material to be removed is thereby extraordinary high impact pressure generated by hollow charge detonation and on finally compressed, tunneled and swirled gas jets displaced or shaken in its structure in such a way that it becomes dust o the dust-like structures disintegrate.

The pressure of the detonating shaped charge increases in the handheld fire tool next concentrated in one focus, with a pressure of approximately 1 million cash can arise. This focal point is mate over side charges accelerated more or less depending on the material and by means of upstream el elements condensed or expanded. For this, this focal point, a gas column training, similar to a projectile in the longitudinal direction of the axis of the soul rotie rend, accelerated further. The gas jet is based on the tornado principle also extremely compressed. An additional acceleration ent still stands in that a compression process of the gas potential within of the upstream elements takes place. In the upstream elements can be an additional scattering effect or concentration effect of this gas column generated after exiting these elements.

The pressure generated acts practically only in the gas jet itself Focus is stretched by the rotation of the gas jet and the finally has the properties of a tightly packaged body. currency When the gas jet is swirled, the focal point is held in the center and swings in the middle of the soul axis through the inflowing Detonation gases. The rotation stabilizes the gas column, similar Lich the well-known bullet swirl.

In addition to the advantages described above, it should also be emphasized that the Distance from the handheld fire tool to the element to be processed or Object hardly matters. Questions of ballistics can also be so like influences of air resistance by the high speed achieved of the gas jet are neglected.

The invention will be explained in more detail below using an exemplary embodiment be tert.

In the accompanying drawing shows

Fig. 1, the handheld fire tool in section

Fig. 2 shows the basic shape of the shaped charge body

Fig. 3 shows the shaped charge body with secondary shaped charges in section

Fig. 4 shows the recoil damping device

As can be seen from Fig. 1, the handheld fire tool described in the exemplary embodiment consists essentially of a base body 1 with a circuit head 3 for receiving a shaped charge body 4 and by means of guide pins 5 so that it is detachably connectable, tubular base body 2 with focal point chamber 6 , attached to it in the working direction subsequent tunneling section 7 and ballast elements 8 or a Streuvor circuit 10 .

The usable in the closure head 3 shaped charge body 4 consists in the exemplary embodiment from various, by means of known explosive molding device formed shaped charge body parts, which are put together with the material to be processed with the hand tool.

In Fig. 2, the basic shape of a hollow body 4 is used in the embodiment. The shaped charge body 4 consists of egg ner by 45 degrees from the apex twisted six-cell in parabola form.

As shown in FIG. 3, the basic shape can be modified with regard to the properties of the material to be processed, but the shaped charge body 4 is always a twisted hyperboloidal or parahyperboloidal body from its apex. Here too, the properties of the workpiece to be machined or the intended type of machining are decisive for the degree of twisting.

The assignment of secondary charges 9 to the actual shaped charge body 4 increases the rotation and acceleration of the gas jet emanating from the shaped charge body 4 when the charge is ignited. The hollow charges are preferably formed out in parabolic or hyper-load forms.

Different ignition points of the parts of the shaped charge body 4 and the parts of the secondary charge 9 or the use of explosives with different burning speeds for the shaped charge body 4 are also suitable measures to shift the speed of rotation of the gas jet and its focal point in the working direction as required.

The gas jet emanating from the shaped charge body 4 and the secondary shaped charges 9 is first focused in the focal point chamber 6 of the base body 2 in a main focal point, this being caused by subsequent detonation gases, preferably those emanating from the shaped charges 9 , into which the tunneling section 7 tapering in the working direction is pressed and is accelerated further there.

In the tunneling section 7 , with the swirling of the inflowing detonation gases, the rotation and compression of the mass of the gas jet already initiated by the formation of the shaped charge body 4 and the secondary shaped charges 9 , if necessary, continues until the plasma stage is reached. At the hyperboloidally profiled tunnel surface of the Vertun nelungsabschnittes 7 , the gas jet is further swirled and ultimately pressed into an axially rotating gas column, which finally settles on the axis of the soul during the tunneling process.

With the scattering ballast 10 and the ballast elements 8 adjoining the tunneling section in the working direction, the cross section of the gas jet can be shaped depending on the shape of the upstream parts. Since the gas jet or the plasma jet can be modeled according to the requirements of the workpiece to be machined or the type of machining.

For better manual handling of the hand-held fire tool, this is provided in the exemplary embodiment according to FIG. 4 with a central recoil nozzle 11 opening into the closure head 3 counter to the working direction with swirling chamber 16 and secondary recoil nozzles 12 with extension chambers 15 .

Not shown in the embodiment, but an advantageous embodiment The invention is, instead of the combustion gas, liquid and solid Accelerate body using a tool-like structure. the Like tools can be used in tunnel construction or for one bring geological deep drilling can be used advantageously.  

With the handheld fire tool described in the exemplary embodiment, it will be possible to very effectively demolish old industrial plants or other buildings in densely populated locations. It will be possible to target a drilling site with the hand-held tool described in the example of the embodiment and then, after ignition of the shaped charge 4, suddenly make the bore with any shape. This application should also represent an advantageous application for mechanical engineering.

Finally, it is summarized that for the processing of work necessary pressures generated in the handheld fire tool and within of the highly compressed gas jet transported to the material in question become. The use of the proposed hand-held fireworks tool thus offers a safe, quick and easy application in many technical areas Areas and rapid implementation of projects for which so far an enor more technical effort would be required.

Claims (6)

1. Hand-held fire tool, characterized in that a hollow charge body is formed by ( 4 ) a hollow body made of shaped explosive which is rotated from the apex, between 0 to 360 degrees, and which is formed with parabolic or hyperload-shaped side charges ( 9 ). is expandable, in the adequately formed from the closure head ( 3 ) of a body part ( 1 ) of the handheld fire tool and that the body part ( 1 ) by means of guide pins ( 5 ) detachably connected to another, tubular body part ( 2 ), wherein the tube-like tapered cavity of the breech head ( 3 ) opens into its focal point chamber ( 6 ), adjoins it a tapering in the working direction and provided with a hyperboloidally designed tunnel surface tunneling section ( 7 ), which arranged before the mouth of the handheld fire tool arranged ballast elements ( 8 ) and scattering circuits ( 10 ) to model the gas or plasma jet. 2. Handheld fire tool according to claim 1, characterized in that starting from the breech head ( 3 ), against the working direction, through break points ( 13 ) for a central recoil nozzle ( 11 ) with an adjoining swirl chamber ( 16 ) and a peripherally arranged ring recoil nozzle ( 14 ) are connected. 3. Handheld fire tool according to claim 1, characterized in that the shaped charge body ( 4 ) and the secondary shaped charges ( 9 ) made of explosives with different combustion speeds NEN. 4. Hand-held fire tool according to claim 1, characterized in that the shaped charge body ( 4 ) and the secondary shaped charges ( 9 ) can have different ignition times. 5. Handheld fire tool according to claim 1, characterized in that the para- and / or hyperboloid shape of the tunnel surface of the vertun nelungsabschnittes ( 7 ) is simply twisted. 6. Handheld fire tool according to claim 1, characterized in that the para- and / or hyperboloid shape of the tunnel surface of the vertun nelungsabschnittes ( 7 ) is progressively rotated.